3.1.1. Case 1 – rectangular distribution of seabed temperature

Assuming a heat source of fixed temperature $\varDelta _T$ and length $L$, the unsteady boundary value problem becomes

(3.3)$$\begin{gather} \frac{\partial T}{\partial t}+\bar{u}\frac{\partial T}{\partial x}=\chi\frac{\partial^2 T}{\partial z^2},\quad \varOmega(x,z,t), \end{gather}$$

(3.4)$$\begin{gather}T=\varDelta_T\left(H[x]-H[x-L]\right), \quad z=0, \end{gather}$$

(3.5)$$\begin{gather}T=0, \quad \sqrt{x^2+z^2}\rightarrow\infty, \end{gather}$$

(3.6)$$\begin{gather}T=0, \quad \varOmega(x,z,0), \end{gather}$$

where $H$ is the Heaviside step function. (It should be noted that Pedley (Reference Pedley1972a,Reference Pedleyb, Reference Pedley1975) obtained an analytical solution to a similar problem.) By utilising a moving coordinate system such that $\xi =x-\bar {u}t$, with the Fourier sine transform and its inverse (Mei Reference Mei1997) the solution is

(3.7)\begin{align} T&=\varDelta_T\left\{\text{Erfc}\left[z\sqrt{\frac{\bar{u}}{4\chi x}}\right]-H\left[x-L\right]\text{Erfc}\left[z\sqrt{\frac{\bar{u}}{4\chi (x-L)}}\right]\right.\nonumber\\ &\quad +H\left[x-\bar{u}t\right]\left(\text{Erf}\left[z\sqrt{\frac{\bar{u}}{4\chi x}}\right]-\text{Erf}\left[\frac{z}{\sqrt{4\chi t}}\right]\right)\nonumber\\ &\quad \left.+H\left[x-\bar{u}t-L\right]\left(\text{Erf}\left[\frac{z}{\sqrt{4\chi t}}\right]-\text{Erf}\left[z\sqrt{\frac{\bar{u}}{4\chi (x-L)}}\right]\right)\right\}, \end{align}

where $\textrm {Erf}$ and $\textrm {Erfc}$ represent the error function and the complementary error function, respectively (Abramowitz & Stegun Reference Abramowitz and Stegun1972). The physical meaning of each term in (3.7) is as follows: the first and third terms represent the unsteady temperature field above the heat source in the region $0< x< L$, the second and fourth terms represent the unsteady component elsewhere, namely in the region $x>L$. Of interest is the steady solution at very large time $T(x,z,t\rightarrow \infty )$, which is given by

(3.8)\begin{equation} T=\varDelta_T\left\{\text{Erfc}\left[z\sqrt{\frac{\bar{u}}{4\chi x}}\right]-H\left[x-L\right]\text{Erfc}\left[z\sqrt{\frac{\bar{u}}{4\chi (x-L)}}\right]\right\}.\end{equation}

By analogy to laminar viscous boundary layer theory, the thermal boundary layer thickness $\delta _T$ is defined as the thickness for which the water temperature is 1 % of the heat source temperature $\varDelta _T$, and can be estimated from (3.8) giving

(3.9)\begin{equation} \text{Erfc}\left[\delta_T\sqrt{\frac{\bar{u}}{4\chi x}}\right]=0.01 \rightarrow\ \delta_T\sim 3.64\times \sqrt{\frac{\chi x}{\bar{u}}}. \end{equation}

From the horizontal velocity component (3.1), we obtain

(3.10)\begin{equation} \delta_T\approx 4.2\times \sqrt{\frac{\chi \sinh^2(kh) x}{A\omega\epsilon}}.\end{equation}

In the ocean typically $h={O}(10)$ m, $A\sim {O}(1)$ m, $\omega ={O}(1)\ \textrm {rad}\ \textrm {s}^{-1}$, $Lk\sim O(1)$ m and $x\sim L$, and we obtain $\delta _T\sim {O}(10^{-2})$ m. In other words, $\delta _T\gg \delta$. An explicit expression for $\delta _T$ in shallow water $kh\ll 1$ can also be determined as

(3.11)\begin{equation} \frac{\delta_T}{\delta}\sim kh\sqrt\frac{x}{A\epsilon}.\end{equation}

In deep water $kh\gg 1$, and

(3.12)\begin{equation} \frac{\delta_T}{\delta}\sim e^{kh}\sqrt{\frac{x}{A\epsilon}},\end{equation}

indicating that the thermal boundary layer thickness is much larger in deep water than in shallow water.

As an example, we consider steady-state temperature fields (3.8) obtained for water depth $h=5$ m, wave amplitude $A=0.25$ m, heat source temperature $\varDelta _T=10\,^{\circ }\textrm {C}$, heat source length $L=5$ m and two values of wave frequency $\omega =1\ \textrm {rad} \ \textrm {s}^{-1}$ and $1.5\ \textrm {rad}\ \textrm {s}^{-1}$. The resulting flow speed is $\bar {u}=[0.0098;0.0061]\ \textrm {m}\ \textrm {s}^{-1}$. Note that these parameters satisfy the criteria for laminar flow stability depicted in figure 1.

Figure 3 displays the steady-state temperature fields for $\omega =1\ \textrm {rad}\ \textrm {s}^{-1}$ and $\omega =1.5\ \textrm {rad}\ \textrm {s}^{-1}$. It can be seen that $\delta _T\sim {O}(10^{-2})$ m at $x=L=5$ m, as predicted by (3.10). Specifically, the growth of $\delta _T$ is very rapid (in $x$) and slows down as $x$ increases. Note that as $\omega$ increases, the velocity above the plate decreases and the thermal boundary layer expands vertically.

Figure 3. Case 1, near-bed steady-state temperature fields for a uniform current profile $\bar {u}$ and a prescribed seabed heat source where $\varDelta _T=10\,^{\circ} \textrm {C}$, $L=5$ m, $h=5$ m and $A=0.25$ m. Wave frequency: (a) $\omega =1\ \textrm {rad}\ \textrm {s}^{-1}$ and (b) $\omega =1.5\ \textrm {rad}\ \textrm {s}^{-1}$. Note that $\delta _T\sim {O}(10^{-2})$ m and increases with wave frequency as predicted by (3.10).

Figure 3 also shows that the temperature decays for large $x$; therefore, the thermal boundary layer is also characterised by a horizontal width. This is of crucial significance when multiple heat sources are considered because they can interact with each other when the distance between them is sufficiently short. In order to characterize the temperature field for the seawater, we examine the location of the maximum of (3.8) for each $x$, which is obtained from

(3.13)\begin{equation} \frac{\partial T}{\partial z}=0\ \rightarrow\ z_{max}=\begin{cases} \displaystyle\sqrt{\frac{4\chi x(x-L)}{L\bar{u}}\log\left(\frac{\sqrt{x}}{\sqrt{x-L}}\right)} , & x>L,\\[10pt] 0, & x\in [0,L]. \end{cases}\end{equation}

The maximum temperature coincides with the heat source ($z_{max}=0$) for $x \leqslant L$ and its vertical elevation above the seabed increases monotonically with horizontal distance $x$ for $x>L$. By substituting (3.13) into (3.8) we obtain the following expression for maximum water temperature as a function of $x$:

(3.14)\begin{align} T_{max}=\begin{cases} \displaystyle\varDelta_T\!\left\{\text{Erfc}\!\left[\sqrt{\frac{ x-L}{L}\log\left( \frac{\sqrt{x}}{\sqrt{x-L}}\right)}\right]-\text{Erfc}\!\left[\sqrt{\frac{ x}{L}\log\left(\frac{ \sqrt{x}}{\sqrt{x-L}}\right)}\right]\right\}, & x>L, \\[10pt] \varDelta_T, & x\in [0,L]. \end{cases} \end{align}

Surprisingly, $T_{max}$ does not depend on fluid velocity $\bar {u}$ and thermal conductivity $\chi$, but only on heat source length $L$ and horizontal position $x$. Figure 4 shows the behaviour of the ratio $T_{max}/\varDelta _T$ as a function of distance from the right edge $(x-L)$ for different heat source lengths $L$. The longer the heat source, the slower the temperature decay. For example, when $L=5$ m, the maximum temperature is 10 % of $\varDelta _T$ after 10 m, as also shown in figure 3.

Figure 4. Ratio $T_{max}/\varDelta _T$ as a function of distance $(x-L)$ from the edge of the heat source for different values of heat source length $L$.

The unsteady seabed heat flux is evaluated from Fourier's law as follows:

(3.15a, 3.15b and 3.15c) $$q = \left\{ {\matrix{ {} \hfill & {\kappa {\rm }\Delta _T\sqrt {\displaystyle{{\bar{u}} \over {x\pi \chi }}} \left[ {1 + \left( {\sqrt {\displaystyle{x \over {\bar{u}t}}} -1} \right)H\left[ {x-\bar{u}t} \right]} \right],} \hfill & {} \hfill & {x\in [0,L],} \hfill \cr {} \hfill & {\kappa {\rm }\Delta _T\sqrt {\displaystyle{{\bar{u}} \over {x\pi \chi }}} \left[ {1-\sqrt {\displaystyle{x \over {x-L}}} + \left( {\sqrt {\displaystyle{x \over {\bar{u}t}}} -1} \right)H\left[ {x-\bar{u}t} \right]} \right.} \hfill & {} \hfill & {} \hfill \cr {} \hfill & {\quad \left. { + \left( {\sqrt {\displaystyle{x \over {x-L}}} -\sqrt {\displaystyle{x \over {\bar{u}t}}} } \right)H\left[ {x-\bar{u}t-L} \right]} \right],} \hfill & {} \hfill & {x > L,} \hfill \cr {} \hfill & {0,} \hfill & {} \hfill & {x < 0.} \hfill \cr } } \right.$$

Expression (3.15a) is always positive and represents the heat flux exchanged between the heat source and the overlying seawater, whereas (3.15b) represents the negative heat flux in $x>L$, beyond the heat source. Note that $q$ tends to infinity as $x^{-1/2}$ and $-(x-L)^{-1/2}$ for $x\rightarrow 0^+$ and $x\rightarrow L+0^+$, respectively, because of the discontinuous gradients in temperature at the edges of the heat source. Integrating (3.15a) and (3.15b), the total unsteady heat fluxes through the region $S_b$ and for $x>L$ are

(3.16)\begin{gather} Q_{S_b}=\int_{0}^Lq\,\mathrm{d}\kern0.7pt x=\begin{cases} \displaystyle\kappa \varDelta_T\frac{\bar{u}t+L}{\sqrt{{\rm \pi}\chi t}}, & t< L/\bar{u},\ x\in [0,L], \\[10pt] \displaystyle\kappa \varDelta_T\sqrt{\frac{4L\bar{u}}{\chi{\rm \pi}}}, & t>L/\bar{u},\ x\in [0,L], \end{cases}\end{gather}

(3.17)\begin{gather} Q_{x>L}=\int_{L}^\infty q\,\mathrm{d}\kern0.7pt x=\begin{cases} \kappa \varDelta_T\dfrac{\bar{u}t-2\sqrt{\bar{u}t(L+\bar{u}t)}} {\sqrt{{\rm \pi}\chi t}}, & t< L/\bar{u},\ x>L, \\[10pt] \kappa \varDelta_T\dfrac{L+2\bar{u}t-2\sqrt{\bar{u}t}(\sqrt{L}+\sqrt{L+\bar{u}t})} {\sqrt{{\rm \pi}\chi t}}, & t>L/\bar{u},\ x>L. \end{cases} \end{gather}

At steady state, the above expressions reduce to

(3.18) \begin{equation} \left.\begin{aligned} &\lim_{t\rightarrow\infty} Q_{S_b}=\kappa \varDelta_T\sqrt{\dfrac{4L\bar{u}}{\chi{\rm \pi}}}, x\in [0,L], \\ &\lim_{t\rightarrow\infty} Q_{x>L}={-}\kappa \varDelta_T\sqrt{\dfrac{4L\bar{u}}{\chi{\rm \pi}}},\quad x>L, \end{aligned}\right\}\end{equation}

with both attaining a maximum when $\bar {u}$ is maximised, demonstrating that the wave-induced flow aids heat exchange. In addition, $Q_{S_b}$ and $Q_{x>L}$ have the same magnitude but opposite sign, and so the total amount of heat in the fluid domain remains constant at steady state (in accordance with the first law of thermodynamics).

3.1.2. Case 2 – rectangular distribution of seabed heat flux distribution

The heat flux is assumed equal to $\mathcal {F}$ through $S_b$, and zero elsewhere. The boundary value problem has Neumann boundary conditions at the seabed, and is given by

(3.19)$$\begin{gather} \frac{\partial T}{\partial t}+\bar{u}\frac{\partial T}{\partial x} =\chi\frac{\partial^2 T}{\partial z^2},\quad \varOmega(x,z,t), \end{gather}$$

(3.20)$$\begin{gather}\frac{\partial T}{\partial z}={-}\frac{\mathcal{F}}{\kappa}\left(H[x]-H[x-L]\right), \quad z=0, \end{gather}$$

(3.21)$$\begin{gather}T=0, \quad \sqrt{x^2+z^2}\rightarrow\infty, \end{gather}$$

(3.22)$$\begin{gather}T=0, \quad \varOmega(x,z,0). \end{gather}$$

A solution is found using the moving coordinate $\xi =x-\bar {u}t$, the Fourier cosine transform along $z$ and its inverse (Mei Reference Mei1997), giving

(3.23)\begin{align} T&=\frac{\mathcal{F}}{\kappa\sqrt{\rm \pi}}\left\{2\sqrt{\frac{x\chi}{\bar{u}}} \exp\left({-\frac{uz^2}{4x\chi}}\right)-z\sqrt{\rm \pi}\,\text{Erfc}\left[z\sqrt{\frac{\bar{u}}{4\chi x}}\right]\right.\nonumber\\ &\quad -H\left[x-L\right]\left(2\sqrt{\frac{(x-L)\chi}{\bar{u}}} \exp\left({-\frac{uz^2}{4\chi(x-L)}}\right)-z\sqrt{\rm \pi}\,\text{Erfc}\left[z\sqrt{\frac{\bar{u}}{4 \chi (x-L)}}\right]\right)\nonumber\\ &\quad +H\left[x-\bar{u}t\right]\left(2\sqrt{t\chi} \exp\left({-\frac{z^2}{4t\chi}}\right)-2\sqrt{\frac{x\chi}{\bar{u}}} \exp\left({-\frac{uz^2}{4\chi x}}\right)\right.\nonumber\\ &\quad \left.-z\sqrt{\rm \pi}\,\text{Erfc}\left[z\sqrt{\frac{\bar{u}}{4\chi x}}\right]- z\sqrt{\rm \pi}\,\text{Erfc}\left[\frac{z}{\sqrt{4\chi t}}\right]\right)\nonumber\\ &\quad -H\left[x-\bar{u}t-L\right]\left(2\sqrt{t\chi} \exp\left({-\frac{z^2}{4t\chi}}\right)-2\sqrt{\frac{(x-L)\chi}{\bar{u}}} \exp\left({-\frac{uz^2}{4\chi (x-L)}}\right)\right.\nonumber\\ &\quad \left.\left.+z\sqrt{\rm \pi}\,\text{Erfc}\left[z\sqrt{\frac{\bar{u}}{4\chi (x-L)}}\right]+z\sqrt{\rm \pi}\,\text{Erfc}\left[\frac{z}{\sqrt{4\chi t}}\right]\right)\right\}. \end{align}

The steady-state solution $T(x,z,t\rightarrow \infty )$ becomes

(3.24)\begin{align} T&=\frac{\mathcal{F}}{\kappa\sqrt{\rm \pi}}\left\{2\sqrt{\frac{x\chi}{\bar{u}}} \exp\left({-\frac{uz^2}{4x\chi}}\right)-z\sqrt{\rm \pi}\,\text{Erfc}\left[z\sqrt{\frac{\bar{u}}{4\chi x}}\right]\right.\nonumber\\ &\quad-\left.H\left[x-L\right]\left(2\sqrt{\frac{(x-L)\chi}{\bar{u}}} \exp\left({-\frac{uz^2}{4\chi (x-L)}}\right)-z\sqrt{\rm \pi}\,\text{Erfc}\left[z\sqrt{\frac{\bar{u}}{4\chi (x-L)}}\right]\right)\right\}. \end{align}

Turning to the temperature profile at the seabed, from (3.24) we obtain

(3.25)\begin{equation} T(x,0,\infty)=\frac{2\mathcal{F}}{\kappa}\sqrt{\frac{\chi}{{\rm \pi}\bar{u}}}\left\{\sqrt{x} -H\left[x-L\right]\sqrt{x-L}\right\},\end{equation}

which has a maximum at $x=L$, namely

(3.26)\begin{equation} T(L,0,\infty)=\frac{2\mathcal{F}}{\kappa}\sqrt{\frac{\chi L}{{\rm \pi}\bar{u}}}. \end{equation}

The foregoing gives an estimate of the temperature at the seabed for a fixed heat flux.

Given the Eulerian-mean velocity $\bar {u}\sim O(10^{-2})\ \textrm {m}\ \textrm {s}^{-1}$ and the thermal conductivity of seawater $\kappa \sim 0.61\ \textrm {W}\ (\textrm {m}\,^{\circ }\textrm {C})^{-1}$, we obtain $T\sim 10^{-2}\mathcal {F}\sqrt {L}\,^{\circ} \textrm {C}$. The temperature field is determined by assuming $\mathcal {F}=10^3\ \textrm {W}\ \textrm {m}^{-2}$ and using the same parameters as in the previous section. Figure 5 depicts the steady-state temperature field for $\omega =1\ \textrm {rad}\ \textrm {s}^{-1}$ and $\omega =1.5\ \textrm {rad}\ \textrm {s}^{-1}$. The temperature contours above the heat source are similar to those in figure 3. To the right of the heat source ($x>L$), the temperature decays more slowly than in case 1. This is due to the absence of heat flux directed towards the seabed for $x>L$.

Figure 5. Case 2: near-bed steady-state temperature fields for a uniform current $\bar {u}$ profile and prescribed seabed heat flux $\mathcal {F}=10^3\ \textrm {W}\ \textrm {m}^{-2}$ where $L=5$ m, $h=5$ m and $A=0.25$ m. Wave frequency: (a) $\omega =1\ \textrm {rad}\ \textrm {s}^{-1}$ and (b) $\omega =1.5\ \textrm {rad}\ \textrm {s}^{-1}$. Above the heat source, the boundary layer thickness is similar to that of case 1 in figure 3, whereas for $x>L$, the temperature decay in the vertical is slower.

3.2.1. Case 3 – prescribed temperature distribution at the seabed

By adopting the approximate vertical profile $\bar {u}_{trap}$ given by (3.2) and a general seabed temperature distribution $T_0(x)$, the steady boundary value problem can be written as

(3.27)$$\begin{gather} \bar{u}_{trap}\frac{\partial T}{\partial x}-\chi\frac{\partial^2 T}{\partial z^2}=0,\quad \varOmega(x,z), \end{gather}$$

(3.28)$$\begin{gather}T=T_0(x), \quad x\in S_b, \end{gather}$$

(3.29)$$\begin{gather}T=0, \quad \sqrt{x^2+z^2}\rightarrow\infty, \end{gather}$$

which is more complicated than the boundary value problem solved by Michele et al. (Reference Michele, Stuhlmeier and Borthwick2021) because of the stepped distribution of the heat source and the trapezoidal velocity profile. Furthermore, it is not possible to identify similarity solutions; instead, it is necessary to pursue a different approach.

Given that the water domain has infinite extent along $x$, we define the Fourier transform $\tilde {T}$ and its inverse as (Mei Reference Mei1997)

(3.30a,b)\begin{equation} \tilde{T}=\int_{-\infty}^{\infty} T(x,z){\rm e}^{-\mathrm{i}\alpha x}\,\mathrm{d}\kern0.7pt x,\quad T=\frac{1}{2{\rm \pi}}\int_{-\infty}^{\infty} \tilde{T}(\alpha,z){\rm e}^{\mathrm{i}\alpha x}\,\mathrm{d}\alpha.\end{equation}

The above expressions define the transformed problem for $T$,

(3.31)$$\begin{gather} \chi\frac{\mathrm{d}^2\tilde{T}}{\mathrm{d}z^2}=\mathrm{i}\alpha \bar{u}_{trap}\tilde{T},\quad \varOmega(\alpha,z), \end{gather}$$

(3.32)$$\begin{gather}\tilde{T}=\tilde{T}_0, \quad z=0, \end{gather}$$

(3.33)$$\begin{gather}\tilde{T}=0, \quad z\rightarrow\infty. \end{gather}$$

Noting that $\bar {u}_{trap}$ has a discontinuous derivative, we decompose the problem in the vertical direction and enforce continuity of temperature and heat flux at the common boundary $z=3\delta /2$, giving

(3.34)$$\begin{gather} \chi\frac{\mathrm{d}^2\tilde{T}^{(1)}}{\mathrm{d}z^2}=\mathrm{i}\alpha z\bar{u}^{(1)}\tilde{T}^{(1)},\quad 0< z<\frac{3\delta}{2}, \end{gather}$$

(3.35)$$\begin{gather}\chi\frac{\mathrm{d}^2\tilde{T}^{(2)}}{\mathrm{d}z^2}= \mathrm{i}\alpha \bar{u}^{(2)}\tilde{T}^{(2)},\quad z>\frac{3\delta}{2}, \end{gather}$$

(3.36)$$\begin{gather}\tilde{T}^{(1)}=\tilde{T}_0, \quad z=0, \end{gather}$$

(3.37)$$\begin{gather}\tilde{T}^{(1)}=\tilde{T}^{(2)}, \quad z=\frac{3\delta}{2}, \end{gather}$$

(3.38)$$\begin{gather}\frac{\mathrm{d}\tilde{T}^{(1)}}{\mathrm{d}z}= \frac{\mathrm{d}\tilde{T}^{(2)}}{\mathrm{d}z}, \quad z=\frac{3\delta}{2}, \end{gather}$$

(3.39)$$\begin{gather}\tilde{T}^{(2)}=0, \quad z\rightarrow\infty. \end{gather}$$

Using (3.30a,b), the required solutions in integral form are

(3.40)$$\begin{gather} T^{(1)}\,{=}\,\frac{3^{2/3}\varGamma\left(\frac{2}{3}\right)}{\rm \pi}{\rm{Re}}\int_{0}^{\infty}\tilde{T}_0 \left\{c_1 \text{Ai}\!\left[z\left(\frac{\mathrm{i}\bar{u}^{(1)}\alpha}{\chi}\right)^{{1/3}}\right]{+}\,c_2 \text{Bi}\left[z\left(\frac{\mathrm{i}\bar{u}^{(1)}\alpha}{\chi}\right)^{{1/3}}\right]\right\} {\rm e}^{\mathrm{i}\alpha x} \,\mathrm{d}\alpha, \end{gather}$$

(3.41)$$\begin{gather}T^{(2)}=\frac{3^{2/3}\varGamma\left(\frac{2}{3}\right)}{\rm \pi}{\rm{Re}}\int_{0}^{\infty}\tilde{T}_0 c_3 \exp\left({-({-}1)^{{1/4}}z\sqrt{\frac{\bar{u}^{(2)}\alpha}{\chi}}+\mathrm{i}\alpha x}\right) \mathrm{d}\alpha, \end{gather}$$

where Ai and Bi are Airy functions of the first and second kind (Abramowitz & Stegun Reference Abramowitz and Stegun1972), $\varGamma$ is the Gamma function, and the complex constants $c_1$, $c_2$ and $c_3$ are listed in Appendix A. The lower limit of the integrals corresponds to 0 because of symmetry. Moreover, the integrands do not contain any singularities. The corresponding solution is readily found numerically as previously undertaken for transient dispersive waves (see e.g. Mei et al. Reference Mei, Stiassnie and Yue2005; Michele et al. Reference Michele, Renzi, Borthwick, Whittaker and Raby2022).

Applying Fourier's law to (3.40), the heat flux at the seabed is given by

(3.42)\begin{equation} q=\kappa\frac{3^{1/3}\varDelta_T\varGamma\left(\frac{2}{3}\right)}{{\rm \pi}\chi^{1/3} \varGamma\left(\frac{1}{3}\right)}{\rm{Re}}\int_{0}^{\infty}\tilde{T}_0 \left(\mathrm{i}\bar{u}^{(1)}\alpha\right)^{{1/3}} \left(c_1 -\sqrt{3} c_2\right){\rm e}^{\mathrm{i}\alpha x} \,\mathrm{d}\alpha, \end{equation}

and the total heat flux in the heat source region $S_b$ is

(3.43)\begin{equation} Q=\int_{{-}L}^L q\,\mathrm{d}\kern0.7pt x=\kappa\frac{3^{1/3}\varDelta_T\varGamma\left(\frac{2}{3}\right)}{{\rm \pi}\chi^{1/3} \varGamma\left(\frac{1}{3}\right)}{\rm{Re}}\int_{0}^{\infty}\tilde{T}_0^2 \left(\mathrm{i}\bar{u}^{(1)}\alpha\right)^{{1/3}} \left(c_1 -\sqrt{3} c_2\right) \mathrm{d}\alpha. \end{equation}

For simplicity, we now assume a heat source $S_b=[0,L]$ as in § 3.1.1 and compare the results against those in figure 3 for the same parameters. Figure 6 shows the temperature field that is similar to that in case 1 (see figure 3) except in the region very close to the heat source. This is due to differences between the velocities in the region $z<3\delta /2$. In case 3 the temperature field bends towards the right more slowly than in case 1, which has consequences for the heat flux, as we show later.

Figure 6. Case 3, near-bed steady-state temperature fields forced by a trapezoidal current profile and prescribed heat source where $\varDelta _T=10\,^{\circ} \textrm {C}$, $L=5$ m, $h=5$ m and $A=0.25$ m. Wave frequency: (a) $\omega =1\ \textrm {rad}\ \textrm {s}^{-1}$ and (b) $\omega =1.5\ \textrm {rad}\ \textrm {s}^{-1}$. The temperature fields are similar to those of case 1 in figure 3 except in the region close to $S_b$.

Next, we compare the heat flux in a trapezoidal flow (3.42) to that in a uniform flow (3.15a)–(3.15b). Figure 7 shows the results for $h=5$ m, $A=0.25$ m and $\omega =[1;1.5]\ \textrm {rad}\ \textrm {s}^{-1}$. The overall behaviour is very similar except near to the right of the heat source edges ($x=0$ and $x=L=5$ m). The differences become larger at diminishing frequency as $\bar {u}^{(2)}$ increases. At such locations, the uniform flow model overestimates the heat flux because of the larger convective effects at the seabed, whereas the linear approximation (3.2) magnifies vertical diffusion above $S_b$ see § 4.

Figure 7. Comparison between heat flux for a trapezoidal current profile (3.42) and a uniform current profile (3.15a)–(3.15b) where $h=5$ m and $A=0.25$ m. Wave frequency: (a) $\omega =1\ \textrm {rad}\ \textrm {s}^{-1}$ and (b) $\omega =1.5\ \textrm {rad}\ \textrm {s}^{-1}$.

3.2.2. Case 4 – prescribed heat flux distribution at seabed

In this case the steady boundary value problem is given by

(3.44)$$\begin{gather} \bar{u}\frac{\partial T}{\partial x}-\chi\frac{\partial^2 T}{\partial z^2}=0,\quad \varOmega(x,z), \end{gather}$$

(3.45)$$\begin{gather}\frac{\partial T}{\partial z}={-}\frac{\mathcal{F}_0(x)}{\kappa}, \quad x\in S_b, \end{gather}$$

(3.46)$$\begin{gather}\frac{\partial T}{\partial z}=0, \quad x\in(-\infty,+\infty)\setminus S_b, \end{gather}$$

(3.47)$$\begin{gather}T=0, \quad \sqrt{x^2+z^2}\rightarrow\infty, \end{gather}$$

where $\mathcal {F}_0(x)$ represents the prescribed heat flux distribution. The solution in integral form is

(3.48)$$\begin{gather} T^{(1)}={-}\frac{3^{1/3}\varGamma\left(\frac{1}{3}\right)}{\kappa{\rm \pi}} {\rm{Re}}\int_{0}^{\infty}\tilde{\mathcal{F}}_0 \left\{c_4 \text{Ai}\left[z\left(\frac{\mathrm{i}\bar{u}^{(1)}\alpha}{\chi}\right)^{{1/3}}\right]+c_5 \text{Bi}\left[z\left(\frac{\mathrm{i}\bar{u}^{(1)}\alpha}{\chi}\right)^{{1/3}}\right]\right\} {\rm e}^{\mathrm{i}\alpha x} \,\mathrm{d}\alpha, \end{gather}$$

(3.49)$$\begin{gather}T^{(2)}={-}\frac{3^{1/3}\varGamma\left(\frac{1}{3}\right)}{\kappa{\rm \pi}} {\rm{Re}}\int_{0}^{\infty}\tilde{\mathcal{F}}_0 c_6\exp\left({-({-}1)^{{1/4}}z\sqrt{\frac{\bar{u}^{(2)}\alpha}{\chi}}+\mathrm{i}\alpha x}\right) \mathrm{d}\alpha. \end{gather}$$

The foregoing expressions are similar to (3.40)–(3.41) but have different constants $c_4$, $c_5$ and $c_6$ (see Appendix B). The expression for temperature at $z=0$ simplifies to

(3.50)\begin{equation} T^{(1)}={-}\frac{3^{-{1/3}}\varGamma\left(\frac{1}{3}\right)}{\kappa{\rm \pi}\varGamma\left(\frac{2}{3}\right)} {\rm{Re}}\int_{0}^{\infty}\tilde{\mathcal{F}}_0 \left(c_4+c_5 \sqrt{3}\right){\rm e}^{\mathrm{i}\alpha x} \,\mathrm{d}\alpha.\end{equation}

We now consider the same parameter values and geometry as in § 3.1.2. Note that the integrand in (3.50) approaches infinity as $\alpha \rightarrow 0$ but the integral is convergent. Its numerical value is obtained by first examining the behaviour for small $\alpha$ (Bender & Orszag Reference Bender and Orszag1991),

(3.51)\begin{equation} \tilde{\mathcal{F}}_0 \left(c_4+c_5 \sqrt{3}\right){\rm e}^{\mathrm{i}\alpha x}\sim \frac{L({-}1)^{{3/4}}3^{{1/3}}\sqrt{\chi}\varGamma\left(\frac{2}{3}\right)}{\sqrt{ \alpha\bar{u}^{(2)}}\varGamma\left(\frac{1}{3}\right)},\quad \alpha\rightarrow 0^+. \end{equation}

The integral (3.50) can be now evaluated as

(3.52)\begin{align} T^{(1)}&\sim{-}\frac{3^{-{1/3}}\varGamma\left(\frac{1}{3}\right)}{\kappa{\rm \pi}\varGamma \left(\frac{2}{3}\right)}{\rm{Re}}\left\{\frac{L({-}1)^{{3/4}}3^{{1/3}}\sqrt{\chi}\varGamma\left( \frac{2}{3}\right)}{\sqrt{\bar{u}^{(2)}}\varGamma\left(\frac{1}{3}\right)}\int_0^{\Delta\alpha} \frac{1}{\sqrt{\alpha}}\,\mathrm{d}\alpha\right.\nonumber\\ &\quad \left.\vphantom{\frac{L({-}1)^{{3/4}}3^{{1/3}}\sqrt{\chi}\varGamma\left( \frac{2}{3}\right)}{\sqrt{\bar{u}^{(2)}}\varGamma\left(\frac{1}{3}\right)}} +\int_{\Delta\alpha}^{\infty}\tilde{\mathcal{F}}_0 \left\{c_4+c_5 \sqrt{3}\right\}{\rm e}^{\mathrm{i}\alpha x} \,\mathrm{d}\alpha\right\}\nonumber\\ &={-}\frac{3^{-{1/3}}\varGamma\left(\frac{1}{3}\right)}{\kappa{\rm \pi}\varGamma\left(\frac{2}{3}\right)} {\rm{Re}}\left\{\frac{2L({-}1)^{{3/4}}3^{{1/3}}\sqrt{\Delta\alpha\chi}\varGamma\left(\frac{2}{3}\right)}{ \sqrt{\bar{u}^{(2)}}\varGamma\left(\frac{1}{3}\right)}\right.\nonumber\\ &\quad \left. \vphantom{\frac{2L({-}1)^{{3/4}}3^{{1/3}}\sqrt{\Delta\alpha\chi}\varGamma\left(\frac{2}{3}\right)}{ \sqrt{\bar{u}^{(2)}}\varGamma\left(\frac{1}{3}\right)}} +\int_{\Delta\alpha}^{\infty}\tilde{\mathcal{F}}_0 \left\{c_4+c_5 \sqrt{3}\right\}{\rm e}^{\mathrm{i}\alpha x} \,\mathrm{d}\alpha\right\}, \end{align}

where $\Delta \alpha$ is the step size used in the numerical discretization, the first term represents the singularity and the second integral is evaluated numerically. Figure 8 shows the temperature field given by (3.48)–(3.49). Comparing this to figure 5, we note similar behaviour except for higher temperatures close to the heat source. The stronger the convective effect the higher the temperature is above $S_b$. This is also evident in figure 9, which shows the seabed temperature variation for vertically uniform (3.50) and vertically trapezoidal (3.25) boundary layer flows.

Figure 8. Case 4, near-bed steady-state temperature fields forced by a trapezoidal current profile for a prescribed seabed heat flux $\mathcal {F}=10^3\ \textrm {W}\ \textrm {m}^{-2}$ where $L=5$ m, $h=5$ m and $A=0.25$ m. Wave frequency: (a) $\omega =1\ \textrm {rad} \ \textrm {s}^{-1}$ and (b) $\omega =1.5\ \textrm {rad}\ \textrm {s}^{-1}$. The temperature fields are similar to those in case 2 (figure 5) except in the region close to $S_b$.

Figure 9. Comparison between the temperature distributions at the seabed for a vertically uniform current (3.25) and a vertically trapezoidal current (3.50) where $\mathcal {F}=10^3\ \textrm {W}\ \textrm {m}^{-2}$, $h=5$ m and $A=0.25$ m. Wave frequency: (a) $\omega =1\ \textrm {rad}\ \textrm {s}^{-1}$ and (b) $\omega =1.5\ \textrm {rad}\ \textrm {s}^{-1}$.

3.3.1. Cases 5 and 7 – Gaussian temperature distribution at the seabed

The boundary value problem to be solved is

(3.53)$$\begin{gather} \bar{u}\frac{\partial T}{\partial x}=\chi\frac{\partial^2 T}{\partial z^2},\quad \varOmega(x,z), \end{gather}$$

(3.54)$$\begin{gather}T=\varDelta_T {\rm e}^{{-}x^2\beta}, \quad z=0, \end{gather}$$

(3.55)$$\begin{gather}T=0, \quad \sqrt{x^2+z^2}\rightarrow\infty, \end{gather}$$

where $\beta >0$ defines the ‘width’ of the Gaussian distribution and $\varDelta _T$ its maximum temperature, which occurs at $x=0$. The following solution for the temperature field is obtained by applying a Fourier transform (3.30a,b):

(3.56)\begin{equation} T=\frac{\varDelta_T}{\sqrt{{\rm \pi} \beta}}{\rm{Re}}\int_0^\infty \exp\left({-\frac{\alpha^2}{4\beta}-z\sqrt{\frac{\mathrm{i}\alpha \bar{u}}{\chi}}+\mathrm{i}\alpha x}\right) \mathrm{d}\alpha .\end{equation}

The heat flux at the seabed $z=0$ becomes

(3.57)\begin{equation} q=\kappa\varDelta_T\sqrt{\frac{\bar{u}}{{\rm \pi} \beta \chi}}\int_0^\infty \sqrt{\alpha}{\rm e}^{-{\alpha^2}/{4\beta}}\cos\left(\frac{\rm \pi}{4}+x\alpha\right)\mathrm{d}\alpha. \end{equation}

The integral is solved in terms of the parabolic cylinder function $D$. Using expression 3.955 in Gradshteyn & Ryzhik (Reference Gradshteyn and Ryzhik2007), we obtain

(3.58)\begin{equation} q=\kappa\varDelta_T\sqrt{\frac{\bar{u}}{\chi}}(2\beta)^{{1/4}} {\rm e}^{-{\beta x^2}/{2}}D_{1/2}(-\sqrt{2\beta}x).\end{equation}

Consider the same parameter values as before: $h=5$ m, $A=0.25$ m, $\varDelta _T=10\,^{\circ} \textrm {C}$, and two values of wave frequency $\omega =1\ \textrm {rad}\ \textrm {s}^{-1}$ and $1.5\ \textrm {rad}\ \textrm {s}^{-1}$, and set $\beta =1\ \textrm {m}^{-2}$. Figures 10 and 11 show the resulting temperature field (3.56) and seabed heat flux distribution (3.58). As the wave frequency increases, the temperature propagates upwards (i.e. to larger values of $z$) and, consequently, the heat flux is smaller in magnitude. It is interesting to examine the behaviour of the maximum and minimum values of heat flux (3.58) depicted in figure 11. First, their location is independent of wave frequency $\omega$ and current magnitude $\bar {u}$ but depends solely on the source width measure $\beta$ (as shown later). Second, the location $x=0$ where the heat source temperature $\varDelta _T$ is at a maximum does not correspond to the location of the maximum of $q$. The locations of the maximum and minimum heat source temperature, $x_{max}$ and $x_{min}$, are estimated from (3.58) by performing a Taylor-series expansion about $x=0$ up to third order, $O(x^3)$, and equating to zero its first derivative. Solving the resulting quadratic,

(3.59a,b)\begin{align} x_{(max,min)}={-}\frac{3\varGamma\left(\frac{1}{4}\right)\mp\sqrt{9\varGamma^2\left(-\frac{1}{4} \right)+40\varGamma^2\left(\frac{1}{4}\right)}}{10\varGamma\left(\frac{1}{4}\right) \sqrt{\beta}}\ \rightarrow\ x_{max}\sim{-}\frac{0.345}{\sqrt{\beta}},\quad x_{min}\sim\frac{1.156}{\sqrt{\beta}}.\end{align}

These closely match the numerically exact locations in figure 11. Outside the heat source region $x\gg 0$ the temperature decreases with decreasing $z$ and the heat flux $q$ becomes negative.

Figure 10. Case 5: near-bed steady-state temperature fields (3.56) for uniform current $\bar {u}$ and Gaussian temperature distribution at the seabed, with $\beta =1\ \textrm {m}^{-2}$, $\varDelta _T=10\,^{\circ} \textrm {C}$, $h = 5$ m and $A=0.25$ m. Wave frequency: (a) $\omega =1\ \textrm {rad}\ \textrm {s}^{-1}$ and (b) $\omega =1.5\ \textrm {rad} \ \textrm {s}^{-1}$.

Figure 11. Steady heat flux $q$ (3.58) with horizontal distance along the bed $x$ for uniform current $\bar {u}$ and Gaussian bed temperature distribution, $\beta =1\ \textrm {m}^{-2}$, $\varDelta _T=10\,^{\circ} \textrm {C}$, $h=5$ m, $A=0.25$ m, and wave frequencies $\omega =[1;1.5]\ \textrm {rad}\ \textrm {s}^{-1}$. Dashed lines indicate the locations of $x_{min}$ and $x_{max}$ from (3.59a,b).

3.3.2. Cases 6 and 8 – Gaussian heat flux distribution along the seabed

In this case the steady boundary value problem reads

(3.60)$$\begin{gather} \bar{u}\frac{\partial T}{\partial x}=\chi\frac{\partial^2 T}{\partial z^2},\quad \varOmega(x,z), \end{gather}$$

(3.61)$$\begin{gather}\frac{\partial T}{\partial z}={-}\frac{\mathcal{F}}{\kappa}{\rm e}^{{-}x^2\beta}, \quad x\in S_b, \end{gather}$$

(3.62)$$\begin{gather}T=0, \quad \sqrt{x^2+z^2}\rightarrow\infty. \end{gather}$$

Following the procedure in § 3.3.1, we obtain

(3.63)\begin{equation} T=\frac{\mathcal{F}}{\kappa}\sqrt{\frac{\chi}{\beta\bar{u}{\rm \pi}}}{\rm{Re}} \int_0^\infty\frac{1}{\sqrt{\mathrm{i}\alpha}} \exp\left({-\frac{\alpha^2}{4\beta}-z\sqrt{\frac{\mathrm{i}\alpha \bar{u}}{\chi}}+\mathrm{i}\alpha x}\right)\mathrm{d}\alpha.\end{equation}

This integral is solved explicitly for temperature at the seabed, $z=0$, giving (Gradshteyn & Ryzhik Reference Gradshteyn and Ryzhik2007)

(3.64)\begin{align} T&=\frac{\mathcal{F}}{\kappa}\sqrt{\frac{\chi}{\beta\bar{u}{\rm \pi}}}\int_0^\infty\frac{1}{\sqrt{\alpha}} {\rm e}^{-{\alpha^2}/{4\beta}}\sin\left(\frac{\rm \pi}{4}+x\alpha\right)\mathrm{d}\alpha \nonumber\\ &=\frac{\mathcal{F}}{\kappa}\sqrt{\frac{\chi{\rm \pi}}{\bar{u}}}\frac{{\rm e}^{-{\beta x^2}/{2}}}{2\sqrt{|x|}}\left[|x|{\rm I}_{-{1/4}}\left(\frac{\beta x^2}{2}\right)+x{\rm I}_{{1/4}}\left(\frac{\beta x^2}{2}\right)\right], \end{align}

where $\textrm {I}$ is the modified Bessel function of the first kind. We again assign the parameters $h=5$ m, $A=0.25$ m, $\mathcal {F}=10^3\ \textrm {W}\ \textrm {m}^{-2}$, $\beta =1\ \textrm {m}^{-2}$, and two values of wave frequency $\omega =1\ \textrm {rad}\ \textrm {s}^{-1}$ and $\omega =1.5\ \textrm {rad}\ \textrm {s}^{-1}$. Figures 12 and 13 show the temperature field in the $x$–$z$ plane (3.63) and the seabed temperature variation in the $x$ direction (3.64). Figure 12 is similar to figure 5 in that the temperature gradient is almost tangential to the seabed at large $x$, and the greater the wave frequency the greater is $T$. In case 6 the minimum of $T$ tends to 0 at a large distance from the seabed, whereas the maximum temperature occurs at the seabed $z=0$ for $x>0$. Performing a Taylor-series expansion of (3.64) about $x=0$ up to third order $O(x^3)$ and equating the first derivative to zero, we obtain

(3.65)\begin{equation} x_{max}={-}\frac{\varGamma\left(\frac{5}{4}\right)-\sqrt{\varGamma^2\left(\frac{3}{4}\right)+ \varGamma^2\left(\frac{5}{4}\right)}}{\varGamma\left(\frac{3}{4}\right)\sqrt{\beta}}\ \rightarrow\ x_{ max}\sim\frac{0.504}{\sqrt{\beta}},\end{equation}

which closely agrees with the maxima of the solutions shown in figure 13. Even for the prescribed heat flux, $x_{max}$ does not depend on the horizontal water particle velocity component but instead depends on $\beta$.

Figure 12. Case 6: near-bed steady-state temperature fields (3.63) for uniform current $\bar {u}$ and Gaussian heat flux distribution at the seabed, with $\beta =1\ \textrm {m}^{-2}$, $\mathcal {F}=10^3\ \textrm {W}\ \textrm {m}^{-2}$, $h=5$ m and $A=0.25$ m. Wave frequency: (a) $\omega =1\ \textrm {rad}\ \textrm {s}^{-1}$ and (b) $\omega =1.5\ \textrm {rad}\ \textrm {s}^{-1}$.

Figure 13. Case 6: steady temperature variation along the seabed (3.64) for uniform current $\bar {u}$ and Gaussian bed heat flux distribution, with $\beta =1\ \textrm {m}^{-2}$, $\mathcal {F}=10^3\ \textrm {W}\ \textrm {m}^{-2}$, $h=5$ m, $A=0.25$ m, and two wave frequencies $\omega =[1;1.5]\ \textrm {rad}\ \textrm {s}^{-1}$. Dashed line depicts the location of $x_{max}$ (3.65).

For heat sources of very small width (i.e. when $\beta \rightarrow \infty$), and noting the behaviour of the modified Bessel functions for large arguments $I_n(x)\sim e^x/(2{\rm \pi} x)$, we obtain, after some straightforward algebra, the approximation

(3.66)\begin{equation} T(x,0)\sim\begin{cases} \dfrac{\mathcal{F}}{\kappa}\sqrt{\dfrac{\chi}{4\bar{u}\beta x}}, & x>0,\\[8pt] 0, & x<0,\\ \end{cases}\end{equation}

which is singular at $x=0$ and decays for large $x$, large $\beta$ and large velocity $\bar {u}$ (i.e. at lower wave frequency).